Researchers from the RIKEN Brain Science Institute report that they successfully used a virus vector to restore the expression of a brain protein and improve cognitive functions, in a mouse model of Alzheimer's disease. Because it is impossible to deliver genes directly to the brain without surgery, the researchers injected the virus in the left ventricle of the heart, as this provides a direct route to the brain.
The NeuroBlate Thermal Therapy System is a new device that uses a minimally invasive, magnetic resonance imaging (MRI)-guided laser system to coagulate, or heat and kill, brain tumors. The MRI basically "cooks" brain tumors in a controlled fashion to destroy them. The first-in-human study of the system finds that it appears to provide a new, safe and minimally invasive procedure for treating recurrent glioblastoma, a malignant type of brain tumor.
People who are hard of hearing can quickly drift into social isolation. Worse, they can also get into dangerous situations, for example when driving or crossing the road. For many of them, their hearing is so damaged that a standard hearing aid is no longer enough. A new device developed by researchers in Europe is intended to improve patients’ hearing and can be implanted during outpatient surgery.
Although bladder cancer is the sixth most common form of cancer in the U.S. and the most expensive to treat, the basic method that doctors use to treat it hasn’t changed much in more than 70 years. A research team may soon be changing that dramatically after having developed a prototype telerobotic platform designed to be inserted through natural orifices—in this case the urethra—that can provide surgeons with a much better view, making it easier to remove tumors.
A sensing system developed at the University of Cambridge is being commercialized in the U.K. for use in rapid, low-cost DNA sequencing, which would make the prediction and diagnosis of disease more efficient, and individualized treatment more affordable.
Researchers at Sandia National Laboratories are developing a medical instrument that will be able to quickly detect a suite of biothreat agents, including anthrax, ricin, botulinum, shiga, and SEB toxin. The device, once developed, approved by the U.S. Food and Drug Administration, and commercialized, would most likely be used in emergency rooms in the event of a bioterrorism incident.
Porous polymer scaffolds fabricated to support the growth of biological tissue for implantation may hold the potential to greatly accelerate the development of cancer therapeutics. Researchers at Rice University, the University of Texas MD Anderson Cancer Center, and Mount Sinai Medical Center reported that 3D scaffolds used to culture Ewing's sarcoma cells were effective at mimicking the environment in which such tumors develop.
Current methods of detecting microRNA (miRNA) can be time consuming and costly: The custom equipment used in such tests costs more than $100,000, and the limited throughput of these systems further hinders progress. Two Massachusetts Institute of Technology alumni are helping to rectify these issues through their fast-growing, Cambridge-headquartered startup, Firefly BioWorks Inc., which provides technology that allows for rapid miRNA detection in a large number of samples using standard laboratory equipment.
Scientists have shown that an enzyme in corn responsible for reading information from DNA can prompt unexpected changes in gene activity—an example of epigenetics that breaks accepted rules of genetic behavior. Though some evidence has suggested that epigenetic changes can bypass DNA’s influence to carry on from one generation to the next, this is the first study to show that this epigenetic heritability can be subject to selective breeding.
The Wyss Institute for Biologically Inspired Engineering at Harvard University has been awarded a $9.25 million contract from the Defense Advanced Research Projects Agency (DARPA) to further advance a blood-cleansing technology developed at the institute. The device uses magnetic nanobeads coated with genetically engineered proteins to cleanse pathogens from the bloodstream, and may one day be used in hospitals or the battlefield.
Heart care is in the midst of a transformation. Many problems that once required sawing through the breastbone and opening up the chest for open heart surgery now can be treated with a nip, twist, or patch through a tube. These minimal procedures used to be done just to unclog arteries and correct less common heart rhythm problems. Now some patients are getting such repairs for valves, irregular heartbeats, holes in the heart and other defects—without major surgery.
Scientists have cracked a 35-year-old mystery about the workings of a revolving molecular motor that is now serving as a model for development of a futuristic genre of synthetic nanomotors that pump therapeutic DNA, RNA, or drugs into individual diseased cells. Their report reveals the mechanisms of these nanomotors in a bacteria-killing virus—and a new way to move DNA through cells
We live in the post-genomic era, when DNA sequence data is growing exponentially. However, for most of the genes that we identify, we have no idea of their biological functions. They are like words in a foreign language, waiting to be deciphered. A new project called CAFA, for Critical Assessment of Function Annotation, is helping channel the flood of data from genome research to deduce the function of proteins.
New research offers a more comprehensive way of analyzing one cell’s unique behavior, using an array of colors to show patterns that could indicate why a cell will or won’t become cancerous. A University of Washington team has developed a new method for color-coding cells that allows them to illuminate 100 biomarkers, a ten-time increase from the current research standard
Ideally, researchers would like to be able to design and build new catalysts from scratch that can do exactly what they want. However, designing—or even modifying—protein enzymes is a very difficult task. Illinois chemists have overcome the issues with size and complexity by using an artificially synthesized DNA sequence to do a protein’s job, creating opportunities for DNA to find work in more areas of biology, chemistry and medicine than ever before
A compact, self-contained sensor recorded and transmitted brain activity data wirelessly for more than a year in early stage animal tests, according to a recent study funded by the National Institutes of Health. In addition to allowing for more natural studies of brain activity in moving subjects, this implantable device represents a potential major step toward cord-free control of advanced prosthetics that move with the power of thought
Three-quarters of the DNA in evolved organisms is wrapped around proteins, forming the basic unit of DNA packaging called nucleosomes, like a thread around a spool. The problem lies in understanding how DNA can then be read by such proteins. Nowphysicists have created a model showing how proteins move along DNA, in a paper just published in EPJ E
Microbes from the human mouth are telling Oak Ridge National Laboratory scientists something about periodontitis and more after they cracked the genetic code of bacteria linked to the condition. The research marks the first time scientists have managed to isolate and cultivate this type of bacterium.
This week, the Wyss Institute for Biologically Inspired Engineering at Harvard University and Sony DADC announced a collaboration that will harness Sony DADC's global manufacturing expertise to further advance the Institute's Organs-on-Chips technologies. Human Organs-on-Chips are research tools composed of a clear, flexible polymer about the size of a computer memory stick, and contain hollow microfluidic channels lined by living human cells
Imitating the structural elements found in most sea sponges, researchers in Germany have created a new synthetic hybrid material that is extremely flexible yet has a mineral content of almost 90%. They recreated the sponge’s spicules using natural calcium carbonate and integrated a protein of the sponge. The invention is even more flexible than its natural counterpart.
Terahertz (THz) radiation, a slice of the electromagnetic spectrum that occupies the middle ground between microwaves and infrared light, is rapidly finding important uses in medical diagnostics. Now, new research performed on lab-grown human skin suggests that short but powerful bursts of THz radiation may both cause DNA damage and increase the production of proteins that help the body fight cancer.
A research team at the National Institute of Materials Science in Japan has recently developed a gel material which is capable of releasing drugs in response to pressure applied by the patient. Three fingers applying force to the site of the gel produces an effect for up to three days. They built the new drug from two materials already used in pharmaceuticals: a saccharide and a natural component of algae.
Researchers at the University of Illinois at Urbana-Champaign have devised a dynamic and reversible way to assemble nanoscale structures and have used it to encrypt a Morse code message. The team started with a template of DNA origami―multiple strands of DNA woven into a tile. They “wrote” their message in the DNA template by attaching biotin-bound DNA strands to specific locations on the tiles that would light up as dots or dashes.
In nature, the bacterium Geobacter sulfurreducens uses a type of natural nanowire, called pili, to transport electrons to remote iron particles or other microbes. The benefits of these wires could also be harnessed by humans for use in fuel cells or bioelectronics. A new study reveals that a core of aromatic amino acids are required to turn these hair-like appendages into functioning electron-carrying biological wires.
New research shows that a tiny piece of RNA has an essential role in ensuring that embryonic tissue segments form properly. The study, conducted in chicken embryos, determined that this piece of RNA regulates cyclical gene activity that defines the timing of the formation of tissue segments that later become muscle and vertebrae.